Bispectral and (glN, glM) Dualities, Discrete Versus Differential

Abstract

Let V = < xλipij(x), i=1,...,n, j=1, ..., Ni > be a space of quasi-polynomials in x of dimension N=N1+...+Nn. The regularized fundamental differential operator of V is the polynomial differential operator Σi=0N AN-i(x)(x d dx)i annihilating V and such that its leading coefficient A0 is a monic polynomial of the minimal possible degree. Let U = < zau qab(u), a=1,...,m, b=1,..., Ma > be a space of quasi-exponentials in u of dimension M=M1+...+Mm. The regularized fundamental difference operator of U is the polynomial difference operator Σi=0M BM-i(u)(τu)i annihilating U and such that its leading coefficient B0 is a monic polynomial of the minimal possible degree. Here (τuf)(u)=f(u+1). Having a space V of quasi-polynomials with the regularized fundamental differential operator D, we construct a space of quasi-exponentials U = <zauqab(u) > whose regularized fundamental difference operator is the difference operator Σi=0N ui AN-i(τu). The space U is constructed from V by a suitable integral transform. Similarly, having U we can recover V by a suitable integral transform. Our integral transforms are analogs of the bispectral involution on the space of rational solutions to the KP hierarchy W. As a corollary of the properties of the integral transforms we obtain a correspondence between solutions to the Bethe ansatz equations of two (glN, glM) dual quantum integrable models: one is the special trigonometric Gaudin model and the other is the special XXX model.

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